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Priority Sesh ☕

Session Types with Priorities in Linear Haskell, based on Sesh.

Building and testing

First off, we'll talk you through some instructions for building and testing Priority Sesh.

Priority Sesh requires at least GHC 9.0.1, as it uses the LinearTypes extension. We build Priority Sesh with Stack, and building and testing is be as simple as running:

cd /path/to/priority-sesh/
stack test

After a bunch of build information, you should see:

priority-sesh> test (suite: test-priority-sesh)

Cases: 16  Tried: 16  Errors: 0  Failures: 0

priority-sesh> Test suite test-priority-sesh passed

Congrats, you did it! 🎉

What if it says Prelude.chr: bad argument: 3925868637?

Unfortunately, Stack hasn't been thoroughly tested with the latest versions of GHC and Cabal, and running stack build sometimes results in Prelude.chr: bad argument: 3925868637. (That one's not on us, we think!) Oddly, stack test does not run into this problem, and builds the entire library! We hope that this quirk disappears once Stack implements official support for the latest GHC versions. If you do run into this problem, running stack clean followed by stack test should solve it.

Paper to practice

In this section, we'll discuss the library, and how it relates to the code in the paper. (We're assuming you've read the paper, and you'd like to see how the actual library fits together.) We'll proceed along the same lines as the paper does—one-shot channels (§2.1), session-typed channels (§2.2), deadlock freedom via process structure (§2.3), and deadlock freedom via priorities (§2.4). However, before we can get started, there's a couple of bits and pieces we need to get started. We'll call that the preamble.

§1 Preamble

Priority Sesh is built on Linear Haskell and its little cousin, linear-base. There's a couple things that are used quite heavily throughout linear-base that the average Haskell programmer perhaps isn't familiar with. We'll discuss linear-base first, and then we'll move on to the parts of priority-sesh which are, essentially, extensions to linear-base, providing the basics which don't yet exist in linear-base.

§1.1 linear-base at a glance

Data.Unrestricted.Linear

The most important module to understand is Data.Unrestricted.Linear, which defines the type classes Consumable and Dupable, which essentially correspond to the ability to drop and copy values:

-- https://github.com/tweag/linear-base/blob/master/src/Data/Unrestricted/Internal/Consumable.hs
class Consumable a where
  consume :: a %1-> ()

-- https://github.com/tweag/linear-base/blob/master/src/Data/Unrestricted/Internal/Dupable.hs
class Consumable a => Dupable a where
  dup2 :: a %1-> (a, a)

(The class for Dupable is a little more complicated than that—it also defines dupV, which allows you to make some set number of copies at the same time—but we don't have to worry about that right now.)

The module provides instances for Consumable and Dupable for most builtin data types—numbers, Bool, (), Void, etc. The module also defines the Ur data type, which wraps unrestricted values, i.e., values which you can use as many as you like without having to resort to consume and dup2:

-- https://github.com/tweag/linear-base/blob/master/src/Data/Unrestricted/Internal/Ur.hs
-- > someLinear :: Ur a %1-> (a,a)
-- > someLinear (Ur a) = (a,a)
data Ur a where
  Ur :: a -> Ur a

We've avoided Ur in the paper, since understanding it requires a slightly deeper understanding of the workings of Linear Haskell, but you may see a few here and there across the library.

Unsafe.Linear

One other important module is Unsafe.Linear, which defines unsafe casts from unrestricted functions to linear functions. For instance,

-- https://github.com/tweag/linear-base/blob/master/src/Unsafe/Linear.hs
toLinear
  :: forall (r1 :: RuntimeRep) (r2 :: RuntimeRep)
     (a :: TYPE r1) (b :: TYPE r2) p.
     (a %p-> b) %1-> (a %1-> b)

The functions in this module are all restricted versions of unsafeCoerce—or rather, unsafeCoerce'd unsafeCoerce, as the builtin version is non-linear! These functions are used throughout linear-base to cast functions from base to linear types when this is safe, rather than reimplementing them.

Control.Functor.Linear

The Monad class provided by base isn't linear. Nor is Functor, Applicative, etc. The module Control.Functor defines linear variants of these classes:

-- https://github.com/tweag/linear-base/blob/master/src/Control/Functor/Linear/Internal/Class.hs
class Applicative m => Monad m where
  -- | @x >>= g@ applies a /linear/ function @g@ linearly (i.e., using it
  -- exactly once) on the value of type @a@ inside the value of type @m a@
  (>>=) :: m a %1-> (a %1-> m b) %1-> m b
System.IO.Linear

Finally, System.IO.Linear defines a linear IO monad (for which it's safe to expose the RealWorld token) and several conversions from "system" IO to linear IO. It also defines toSystemIO, but does not export it, as it's unsafe. Therefore, you'll see us redefine it at several places in our code.

§1.2 What's missing in linear-base?

The linear-base library is still somewhat immature, and only covers a small fraction of the actual base library. We'll briefly cover the things we found missing, and where we define these. One thing you've probably caught onto by now is that every module path in linear-base ends in Linear, which is a naming convention we've taken over in our library.

Control.Concurrent.Linear

The first thing that's missing is, essentially, all concurrency primitives. To get started, we cast forkIO to a linear type, and make ThreadId consumable.

Control.Concurrent.MVar.Linear

The second thing that's missing is MVar. Priority Sesh relies quite heavily on MVar as a primitive for building one-shot channels. In this module, we cast newEmptyMVar, takeMVar, and putMVar to linear types, and lift them into the linear IO monad:

newEmptyMVar :: Linear.IO (Ur (MVar a))
takeMVar     :: MVar a %1-> Linear.IO a
putMVar      :: MVar a %1-> a %1-> Linear.IO ()

We also make MVar consumable. The rationale for this is explained in §2.1 under "Cancellation". In short, throwing away an MVar happens to have exactly the semantics we need from one-shot channels to get the semantics we need for session cancellation.

Data.Type.Nat and Data.Type.Priority

The priority-based variant of the library relies quite heavily on type-level naturals. GHC ships with GHC.TypeNats out of the box, which is what we are currently using. If you check Data.Type.Nat, you'll see that the file contains two implementations type-level naturals—one which re-exports GHC.TypeNats along with a few other primitives, and one which builds type-level naturals up from scratch. This allowed us to quickly explore different designs, and compare how many of the constraints they could automatically discharge, which was especially relevant while exploring the interaction between priorities and recursion (see §2.4 under "Recursion"). The Data.Type.Priority module extends the basic operations on naturals to priorities.

§2.1 One-shot channels

The module Control.Concurrent.OneShot.Linear implements the one-shot channels described in §2.1 of the paper. The names were change a little for the paper, but otherwise the implementation follows the paper.

Paper Code
Send₁ SendOnce
Recv₁ RecvOnce
new₁ new
send₁ send
recv₁ recv
Sync₁ SyncOnce
newSync₁ newSync
sync₁ sync

When imported, the names from the OneShot module are generally referred qualified to as OneShot.new, OneShot.send, OneShot.recv, etc.

The module Test.OneShot has some simple tests for the one-shot channels. The first test checks that a simple ping works, and doesn't throw an exception:

pingWorks :: Test
pingWorks = TestLabel "ping" $ TestCase (assert ping)
  where
    ping = do
      (chan_s, chan_r) <- new
      void $ forkIO (send chan_s ())
      recv chan_r

The assert primitive simply checks that no exception is thrown. (If the argument passed returns a Bool, it also checks that the value is True.) The second test check that cancelAndRecv and cancelAndSend behave appropriately (see §2.1 under "Cancellation"):

cancelWorks :: Test
cancelWorks = TestLabel "cancel" $ TestList
  [ TestLabel "recv" $ TestCase (assertBlockedIndefinitelyOnMVar @() cancelAndRecv)
  , TestLabel "send" $ TestCase (assert cancelAndSend)
  ]
  where
    -- Server cancels, client tries to receive.
    cancelAndRecv = do
      (chan_s, chan_r) <- new
      void $ forkIO (return (consume chan_s))
      recv chan_r

    -- Server cancels, client tries to send.
    cancelAndSend = do
      (chan_s, chan_r) <- new
      void $ forkIO (return (consume chan_r))
      send chan_s ()

§2.2 Session-typed channels

The module Control.Concurrent.Session.Linear implements the session-typed channels described in §2.2 of the paper. The names should match those in the paper, and the implementations should generally match as well, though the implementations of new in the code are in point-free style.

The module Test.Session contains some tests for the session-typed channels. For instance, it tests a calculator service:

type NegServer = Recv Int (Send Int End)
type AddServer = Recv Int (Recv Int (Send Int End))

type CalcServer = Offer NegServer AddServer
type CalcClient = Dual CalcServer

-- |Test using the calculator server for negation.
calcWorks :: Test
calcWorks = TestLabel "calc" $ TestList
  [ TestLabel "neg" $ TestCase (assert negMain)
  , TestLabel "add" $ TestCase (assert addMain)
  ]
  where
    negMain = connect calcServer negClient
    addMain = connect calcServer addClient

    -- Calculator server which offers negation and addition.
    calcServer :: CalcServer %1 -> Linear.IO ()
    calcServer s = offerEither s match
      where
        match :: Either NegServer AddServer %1 -> Linear.IO ()
        match (Left s)  = do
          (x, s) <- recv s
          s <- send (negate x, s)
          close s
        match (Right s) = do
          (x, s) <- recv s
          (y, s) <- recv s
          s <- send (x + y, s)
          close s

    -- Calculator client which chooses (negate 42).
    negClient :: CalcClient %1 -> Linear.IO Bool
    negClient s = do
      s <- selectLeft s
      s <- send (42, s)
      (x, s) <- recv s
      close s
      return $ x == -42

    -- Calculator client which chooses (4 + 5).
    addClient :: CalcClient %1 -> Linear.IO Bool
    addClient s = do
      s <- selectRight s
      s <- send (4, s)
      s <- send (5, s)
      (x, s) <- recv s
      close s
      return $ x == 9

And a recursive summation service, as described in §2.1 under "Recursion":

newtype SumServer
  = SumServer (Offer (Recv Int SumServer) (Send Int End))

newtype SumClient
  = SumClient (Select (Send Int SumClient) (Recv Int End))

instance Consumable SumServer where
  consume (SumServer s) = consume s

instance Consumable SumClient where
  consume (SumClient s) = consume s

instance Session SumServer where
  type Dual SumServer = SumClient
  new = bimap SumServer SumClient <$> new

instance Session SumClient where
  type Dual SumClient = SumServer
  new = bimap SumClient SumServer <$> new

sumWorks :: Test
sumWorks = TestLabel "sum" $ TestCase (assert main)
  where
    main = connect (sumServer 0) sumClient

    -- Server which offers summation.
    sumServer :: Int %1 -> SumServer %1 -> Linear.IO ()
    sumServer tot (SumServer s) = offerEither s (match tot)
      where
        match :: Int %1 -> Either (Recv Int SumServer) (Send Int End) %1 -> Linear.IO ()
        match tot (Left s) = do
          (x, s) <- recv s
          sumServer (tot + x) s
        match tot (Right s) = do
          s <- send (tot, s)
          close s

    -- Client which sums [1..6].
    sumClient :: SumClient %1 -> Linear.IO Bool
    sumClient (SumClient s) = do
      s <- selectLeft s
      SumClient s <- send (1, s)
      s <- selectLeft s
      SumClient s <- send (2, s)
      s <- selectLeft s
      SumClient s <- send (3, s)
      s <- selectLeft s
      SumClient s <- send (4, s)
      s <- selectLeft s
      SumClient s <- send (5, s)
      s <- selectLeft s
      SumClient s <- send (6, s)
      s <- selectRight s
      (tot, s) <- recv s
      close s
      return $ tot == 21

It also tests the behaviour for cancellation, and implements a more complex, recursive variant of the cyclic scheduler presented in §2.4 under "Cyclic Scheduler", but without guaranteeing deadlock freedom.

§2.3 Deadlock freedom via process structure

The module Control.Concurrent.Session.DF.Tree.Linear exports the deadlock-free interface described in §2.3 of the paper. This modules doesn't define any new function, as connect is already defined in Control.Concurrent.Session.Linear. Rather, it re-exports the definitions from Control.Concurrent.Session.Linear, but hides new.

There are no tests associated with this module, as it doesn't implement any new functionality.

§2.4 Deadlock freedom via priorities

Finally, Control.Concurrent.Session.DF.Priority.Linear defines the priority-based session-typed channels described in §2.4 of the paper. This modules defines the Sesh monad with the extension described in §2.4 under "Safe IO", but the order of the arguments was changed for the paper, as mentioned, for typographical reasons.

newtype Sesh
  (t :: Type)     -- ^ Session token.
  (p :: Priority) -- ^ Lower priority bound.
  (q :: Priority) -- ^ Upper priority bound.
  (a :: Type)     -- ^ Underlying type.
  = Sesh (Linear.IO a)

(The function unsafeRunSesh is defined separately, rather than via record syntax, to ensure it has a linear type.)

The module defines >>>= and ireturn—the names derive from those frequently used by indexed monads—as well as =<<<, >>>, and <<<. The Sesh monad implements Data.Functor as well as Control.Functor—these are two different Functor classes provided by linear-base, which differ in their linearity. Unfortunately, the types for >>>= and ireturn don't fit the standard Monad class.

The implementation of the Session monad and the communication primitives follow the implementations in Control.Concurrent.Session.Linear, but wrapped in the Sesh monad. A previous version of the library wrapped the primitives from Control.Concurrent.Session.Linear, but this made it needlessly complex to write user-defined instances of the Session class, as is needed for recursive sessions.

The module Test.Session.Priority contains some tests for the priority-based channels. Most importantly, it starts by rebinding do-notation to the Sesh monad:

{-# LANGUAGE RebindableSyntax #-}

-- ... other stuff ...

import Control.Concurrent.Session.DF.Priority.Linear as Session

-- ... other stuff ...

return :: a %1 -> Sesh t 'Top 'Bot a
return = Session.ireturn

(>>=) :: (q < p') =>
  Sesh t p q a %1 ->
  (a %1 -> Sesh t p' q' b) %1 ->
  Sesh t (Min p p') (Max q q') b
(>>=) = (Session.>>>=)

(>>) :: (q < p') =>
  Sesh t p q () %1 ->
  Sesh t p' q' b %1 ->
  Sesh t (Min p p') (Max q q') b
(>>) = (Session.>>>)

fail :: String -> Sesh t p q a
fail = error

It implements largely the same tests as before: a simple ping, a calculator service, cancellation, etc.

It contains commented-out code for a deadlocking process, a slight variant of woops from §2.3 in the paper:

deadlockFails :: Test
deadlockFails = TestLabel "deadlock" $ TestCase (assert (runSeshIO woops))
  where
    woops :: Sesh t _ _ ()
    woops = do
      (s1, r1) <- new :: Sesh t _ _ (Send t _ Void (), Recv t _ Void ())
      (s2, r2) <- new :: Sesh t _ _ (Send t _ Void (), Recv t _ Void ())
      fork $ do (void, ()) <- recv @0 r1
                send @1 (void, s2)
      (void, ()) <- recv @0 r2
      send @1 (void, s1)

This code fails to compile with the error that 0 ~ 1 doesn't hold, which happens because our deadlocking code forced us to annotate dual actions with @0 and @1.

Finally, the module contains the code for the finite cyclic scheduler from §2.4 under "Cyclic Scheduler".

TODO

  • Factor out Cancellable a into a separate newtype which wraps a into a Weak reference, such that Cancellable (Send a s) implements Consumable and has a cancel method.
  • Provide alias Send a s for Cancellable (Send a s) in separate module.

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